JPWO2019111409A1 - Cup type wave gear device - Google Patents

Abstract

The wave gear device (1) has a rigid internal gear (2), a flexible external gear (3), and a wave generator (4). Before being bent by the wave generator (4), the inner diameter of the cylindrical body portion (11) of the external gear (3) has the smallest rear end inner diameter D, and is open from the rear end (11a) to the open end. It gradually increases toward (11b). When the minor diameter of the elliptical inner peripheral surface of the open end (11b) of the cylindrical body (11) in the state of being bent by the wave generator (4) is D1, D1 ≦ D. The external gear (3) having the tapered cylindrical body (11) is suitable for manufacturing by molding such as casting, and can alleviate excessive contact of the wave bearing.

Description

  The present invention relates to a wave gear device, and more particularly, to a cup-type wave gear device having a cup-shaped flexible external gear.

  As a cup-type wave gear device, there is known a cup-shaped external gear in which a cylindrical body portion in a cup-shaped external gear is tapered. Patent Document 1 proposes a wave gear device including an external gear having this shape.

  In the wave gear device described in Patent Literature 1, a rotation transmitting member for bending the radius of the rear end of the cylindrical body of the external gear on the diaphragm side to bend the opening end portion of the cylindrical body in an elliptical shape. (Wave generator) is made smaller than the minor axis radius of the elliptical contour. In a state where the open end portion of the external gear is bent in an elliptical shape, the open end portion where the external teeth are formed is radially outward toward the open end at all positions in the circumferential direction. It becomes a tapered shape that spreads out.

JP-A-2017-137882

  A wave generator for bending an external gear into an elliptical shape generally includes a plug which is a rigid body having an elliptical outer peripheral surface, and an open end of the elliptical outer peripheral surface of the plug and a cylindrical body of the external gear. And a wave bearing mounted between the side parts. When the cylindrical body of the external gear has a large taper angle toward the open end thereof, the gap between the outer ring of the wave bearing and the inner peripheral surface at the open end of the cylindrical body is provided. Contact is excessively skewed.

  When the open end portion in which the external teeth are formed is supported by the wave bearing in a single contact state, an unnecessary thrust force acts on each portion, and the engagement depth of the external gear with respect to the internal gear is reduced. There are adverse effects, such as an inability to form an appropriate meshing state due to a large difference in direction. In order to improve the meshing state in the tooth trace direction, it is necessary to take countermeasures such as forming the internal gear into a conical tooth shape, which also has an adverse effect such as an increase in manufacturing cost.

  The present invention has been made by paying attention to a conventional external gear having a tapered cylindrical body. An object of the present invention is to provide an external gear having a tapered cylindrical body which is suitable for manufacturing by press forming, forging, casting, and other mold forming, and which can mitigate the adverse effects caused by wave bearing half contact. And a cup-shaped wave gear device.

  The cup-shaped wave gear device of the present invention includes a rigid internal gear, a flexible external gear, and a wave generator. The external gear includes a cylindrical body that can bend in the radial direction, a diaphragm extending from a rear end, which is one end of the cylindrical body, toward the center axis of the cylindrical body, and a center side of the diaphragm. And a rigid annular or disk-shaped boss formed at the portion, and external teeth formed on the outer peripheral surface portion on the side of the open end which is the other end of the cylindrical body. In addition, the wave generator bends a portion of the cylindrical body portion on the side of the open end where the external teeth are formed into an elliptical shape, and engages with the internal gear at a plurality of positions separated in the circumferential direction. Is formed.

Further, the cylindrical body of the external gear has a shape satisfying the following conditions. That is, in a state before being bent by the wave generator, the inner diameter of the cylindrical body portion has the smallest inner diameter at the rear end (rear inner diameter), and gradually increases from the rear end toward the open end. The outer diameter of the cylindrical body also has the smallest outer diameter at the rear end, and gradually increases from the rear end toward the open end. In a state where the cylindrical body is bent by the wave generator, the minor diameter of the elliptical inner peripheral surface at the open end of the cylindrical body is equal to or smaller than the rear end inner diameter of the cylindrical body. . That is, when the rear end inner diameter that is the minimum inner diameter is D, and the minor diameter of the elliptical inner peripheral surface of the open end of the cylindrical body portion is D1 in a state where it is bent by the wave generator,
D1 ≦ D
It is.

  In the wave gear device of the present invention, the initial shape (shape before being bent) of the cylindrical body portion of the external gear is a tapered shape slightly expanding toward the opening end. In the case where the external gear is manufactured by die forming such as forging, casting, or press forming, the external gear can be formed into a shape having an allowance.

  The cylindrical body in the state of being bent into an elliptical shape is as follows. At the major axis position of the elliptical shape on the side of the opening end where the external teeth are formed, a taper state is formed that spreads slightly outward in the radial direction toward the opening end. On the other hand, at the short axis position, a state where there is no inclination toward the opening end, or an inverted taper state where the taper slightly narrows inward in the radial direction is formed. Since the tapered angle of the cylindrical body is small, the contact of the wave bearing due to the inclination of the opening end at the long axis position where the meshing state of both gears is formed is also reduced.

  Here, as the diaphragm, a disk-shaped diaphragm having a predetermined thickness extending from a rear end of the cylindrical body in a direction perpendicular to the central axis can be used.

  Further, as the diaphragm, a frustoconical diaphragm extending from the rear end in a direction inclined at a predetermined angle with respect to a direction orthogonal to the central axis can also be used. For example, as the diaphragm, a tapered diaphragm having a predetermined thickness in which the inner diameter and the inner diameter gradually decrease from the rear end of the cylindrical body toward the side opposite to the open end along the central axis can be used.

  In any shape of the diaphragm, a portion connected to the rear end of the cylindrical body has a maximum outer diameter and a maximum inner diameter, and a portion connected to the boss has a minimum outer diameter and a minimum inner diameter.

(A) is a schematic longitudinal sectional view showing a wave gear device to which the present invention is applied, and (b) is a schematic end view thereof. (A) is a longitudinal sectional view showing the external gear before being bent into an elliptical shape, (b) is a longitudinal sectional view showing a section including a long axis in a state bent into an elliptical shape, (c) is a longitudinal sectional view showing a section including a short axis in a state of being bent into an ellipse. (A) is explanatory drawing which shows the taper shape of the cylindrical trunk | drum of the external gear of cup shape, (b) is the circular inner peripheral surface shape of the rear end, the circular inner peripheral surface shape of an opening end, and the opening. It is explanatory drawing which shows the elliptical inner peripheral surface shape of an edge. It is explanatory drawing which shows the example of the external gear provided with the diaphragm of a different shape.

  Hereinafter, an embodiment of a cup-type wave gear device to which the present invention is applied will be described with reference to the drawings. FIG. 1A is a schematic longitudinal sectional view showing a cup-type wave gear device to which the present invention is applied, and FIG. 1B is a schematic end view thereof. The cup-type wave gear device 1 (hereinafter, simply referred to as “wave gear device 1”) includes a ring-shaped rigid internal gear 2 and a cup-shaped flexible outer gear coaxially arranged inside the ring-shaped internal gear 2. The gear includes a gear 3 and a wave generator 4 fitted inside the gear 3.

  The cup-shaped external gear 3 is connected to a cylindrical body 11, a disk-shaped diaphragm 12 extending inward in the radial direction from a rear end 11 a which is one end thereof, and an inner peripheral edge of the diaphragm 12. A boss 13 which is an annular rigid body, and external teeth 3a formed on an outer peripheral surface portion on an opening end 11b side which is the other end of the cylindrical body portion 11 are provided. The initial shape of the cylindrical body 11 is a tapered shape slightly expanding from the rear end 11a toward the open end 11b.

  The diaphragm 12 has a curved portion 12a smoothly connected to the rear end 11a of the cylindrical body 11 and curved at a right angle toward the center axis 1a, and a diaphragm linearly extending radially from the end of the curved portion 12a. It has a main body portion 12b and a boss-side root portion 12c connected to the boss 13 with a thickness gradually increasing continuously from the inner peripheral edge of the diaphragm main body portion 12b.

  The wave generator 4 includes a cylindrical hub 21, a plug 23 attached to the outer peripheral surface of the hub 23 via an Oldham coupling 22, and a wave bearing 25 mounted on an elliptical outer peripheral surface 24 of the plug 23. The wave bearing 25 of this embodiment is formed of a ball bearing. The wave generator 4 is fitted inside a portion of the cylindrical body 11 of the external gear 3 where the external teeth 3a are formed. The portion of the perfect circular cylindrical body 11 on the side of the opening end 11b is bent by the wave generator 4 into an elliptical shape. The external teeth 3a bent in the elliptical shape are engaged with the internal teeth 2a of the internal gear 2 at both ends of the major axis Lmax of the elliptical shape.

  When the wave generator 4 rotates, the meshing position of the external gear 3 with respect to the internal gear 2 moves in the circumferential direction. As a result, as is well known, relative rotation corresponding to the difference in the number of teeth between the two gears 2 and 3 occurs between the two gears, and one of the gears can be fixed, and the reduced rotation can be extracted from the other gear.

  FIG. 2A is a longitudinal sectional view showing the external gear 3 in an initial state before being bent into an elliptical shape, and FIG. 2B is a cross section including the major axis Lmax in a state where the external gear 3 is bent into an elliptical shape. FIG. 2 (c) is a longitudinal sectional view showing a section including the short axis Lmin in a state of being bent into an elliptical shape. FIG. 3A is an explanatory view showing a tapered shape of a cylindrical body portion of a cup-shaped external gear, and FIG. 3B is a diagram showing a circular inner peripheral surface shape before bending of a rear end 11a and an open end 11b. FIG. 4 is an explanatory diagram showing a circular inner peripheral shape before bending and an elliptical inner peripheral shape after bending of an open end 11b.

  FIG. 2A shows an initial state of the cylindrical body 11 of the external gear 3, that is, a state before the wave generator 4 is fitted inside and bent into an elliptical shape. In this state, the shape of the inner peripheral surface at each position in the direction of the central axis 1a is a perfect circle. The cylindrical body 11 has a tapered shape that extends from the rear end 11a toward the open end 11b. Specifically, the inner diameter of the cylindrical body portion 11 in the initial state is such that the rear end inner diameter D at the rear end 11a is the smallest, and gradually increases from the rear end 11a toward the open end 11b. The opening end inner diameter Do is the maximum.

  In this example, when viewed in a cross section including the central axis 1a, the inner peripheral surface 11c of the cylindrical body 11 extends radially outward with a constant taper angle from the rear end 11a to the open end 11b. Has spread. The cylindrical body 11 has substantially the same plate thickness, and the outer diameter of the cylindrical body 11 also extends from the rear end 11a toward the external teeth 3a on the side of the open end 11b on the outer peripheral surface 11d. It gradually increases linearly with a constant taper. The external gear 3 has a shape having an allowance in the case where it is manufactured as a whole by die forming such as forging, casting, and press forming.

As shown in FIGS. 2 (b), 2 (c), and 3, after being bent into an elliptical shape by the wave generator 4, the open end 11b of the cylindrical body 11 has an elliptical inner periphery. Surface. The ellipse that defines the elliptical inner peripheral surface is C (D1, D2), its minor axis is D1, and its major axis is D2. Further, C (D) is a perfect circle that defines the rear end inner peripheral surface of the rear end 11 a of the cylindrical body 11 before bending, and D is the inner diameter (rear end inner diameter) of the open end 11 b. The perfect circle defining the surface is C (Do), and its inner diameter is Do. The short diameter D1, the long diameter D2, the inside diameter D of the rear end 11a, and the inside diameter Do of the open end 11b satisfy the following relationship.
D1 ≦ D <Do <D2

  In the elliptically bent state, the portion of the cylindrical body 11 where the external teeth 3a are formed is slightly outward in the radial direction toward the open end 11b at the position of the major axis Lmax of the elliptical shape. To a tapered state. On the other hand, at the position of the short axis Lmin, the portion where the external teeth 3a are formed has no inclined state toward the opening end 11b, or has an inversely tapered state in which the external teeth 3a are slightly narrowed inward in the radial direction. . Since the taper angle of the cylindrical body portion 11 is small, at the position of the long axis Lmax where the engagement state of the internal teeth 2a and the external teeth 3a is formed, one end of the wave bearing 25 caused by the inclination of the opening end 11b is formed. The hit is reduced.

  In the tapered cylindrical body 11, when the inner peripheral surface 11c and the outer peripheral surface 11d are viewed in a cross section including the central axis 1a, a convex or concave curve is formed from the rear end 11a toward the open end 11b. It is also possible to specify Also, different taper angles can be given to the inner peripheral surface 11c and the outer peripheral surface 11d.

  FIGS. 4A to 4D are explanatory diagrams showing examples of external gears provided with diaphragms having different shapes. In these figures, parts corresponding to the respective parts of the external gear 3 are denoted by the same reference numerals.

  The diaphragm 12A of the external gear 3A shown in FIG. 4A has a predetermined angle from the rear end 11a of the cylindrical body 11 to the side orthogonal to the central axis 1a on the opposite side to the open end 11b. It has a truncated cone shape extending in the direction of inclination. Conversely, the diaphragm 12B of the external gear 3B shown in FIG. 4B has a flat truncated cone shape that is inclined at a slight angle from the rear end 11a of the cylindrical body 11 toward the open end 11b. I have.

  The diaphragm 12C of the external gear 3C shown in FIG. 4C has an inner diameter and an inner diameter that gradually decrease from the rear end 11a of the cylindrical body 11 toward the side opposite to the open end 11b along the central axis 1a. Has a tapered shape. The outer peripheral surface of the diaphragm 12C is defined by a convex curved surface, and the inner peripheral surface thereof is defined by a concave curved surface. The diaphragm 12D of the external gear 3D shown in FIG. 4D also has an inner diameter and an inner diameter that gradually decrease from the rear end 11a of the cylindrical body 11 toward the side opposite to the open end 11b along the central axis 1a. It has a tapered shape with a predetermined thickness. The outer peripheral surface of the diaphragm 12D is defined by a convex curved surface and a concave curved surface, and the inner peripheral surface thereof is defined by a concave curved surface and a convex curved surface.

Each of the external gears 3 </ b> A to 3 </ b> D has a tapered cylindrical body 11. Further, in the diaphragms 12A to 12D, a portion connected to the rear end 11a of the cylindrical body 11 has a maximum outer diameter and a maximum inner diameter, and a portion connected to the boss 13 has a minimum outer diameter and a minimum inner diameter. External gears 3A to 3D provided with these diaphragms 12A to 12D can be used instead of the external gear 3 described above.

Further, as the diaphragm, a frustoconical diaphragm extending from the rear end in a direction inclined at a predetermined angle with respect to a direction orthogonal to the central axis can also be used. For example, as the diaphragm, a tapered diaphragm having a predetermined thickness in which the inner diameter and the outer diameter are gradually reduced from the rear end of the cylindrical body toward the side opposite to the open end along the central axis can be used. .

The diaphragm 12C of the external gear 3C shown in FIG. 4 (c) has an inner diameter and an outer diameter gradually decreasing from the rear end 11a of the cylindrical body 11 toward the side opposite to the open end 11b along the central axis 1a. It has a tapered shape. The outer peripheral surface of the diaphragm 12C is defined by a convex curved surface, and the inner peripheral surface thereof is defined by a concave curved surface. The diaphragm 12D of the external gear 3D shown in FIG. 4D also has an inner diameter and an outer diameter that gradually decrease from the rear end 11a of the cylindrical body 11 along the central axis 1a toward the side opposite to the open end 11b. Of a predetermined thickness. The outer peripheral surface of the diaphragm 12D is defined by a convex curved surface and a concave curved surface, and the inner peripheral surface thereof is defined by a concave curved surface and a convex curved surface.

Claims (2)

With a rigid internal gear, a flexible external gear, and a wave generator,
The external gear has a cylindrical body that can be flexed in the radial direction, a diaphragm extending from a rear end, which is one end of the cylindrical body, toward a center axis of the cylindrical body, and a diaphragm of the diaphragm. A rigid annular or disk-shaped boss formed on the center portion, and external teeth formed on the outer peripheral surface portion on the side of the open end which is the other end of the cylindrical body,
The wave generator bends the portion of the cylindrical body on the side of the open end into an elliptical shape, and at a plurality of positions separated in the circumferential direction, the external teeth of the external gear are the internal gear. The meshing part that meshes with the internal teeth of the
In a state before being bent by the wave generator, the inner diameter of the cylindrical body has a minimum rear end inner diameter at the rear end, and gradually increases from the rear end toward the open end, The outer diameter of the cylindrical body is minimum at the rear end, and gradually increases from the rear end toward the open end,
In the state of being bent by the wave generator, the minor diameter of the elliptical inner peripheral surface of the open end of the cylindrical body is the same as the inner diameter of the rear end of the cylindrical body, or the rear end thereof. A cup-shaped wave gear device smaller than the inner diameter of the cup. In claim 1,
The diaphragm,
A disk-shaped diaphragm of a predetermined thickness extending from the rear end of the cylindrical body in an orthogonal direction orthogonal to the central axis, or
A cup-shaped wave gear device, which is a truncated conical diaphragm extending in a direction inclined at a predetermined angle with respect to the orthogonal direction from the rear end.

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